CN114411872B - Economical intelligent water flow distribution management method and system - Google Patents

Abstract

The application relates to an economical intelligent water flow distribution management method and system, and relates to the technical field of water flow distribution. The device comprises two water inlet pipes and two water reservoirs, wherein the water inlet pipes are in one-to-one correspondence with the water reservoirs, the two water inlet pipes are respectively provided with a direct connecting pipe and a branch connecting pipe in a communicating manner, the direct connecting pipe is connected with the water reservoir corresponding to the water inlet pipe connected with the direct connecting pipe, and the branch connecting pipe is connected with the other water reservoir; wherein, a regulating component for changing the water flow in the straight connecting pipe and the separating connecting pipe is connected between the straight connecting pipe on any water inlet pipe and the separating connecting pipe on the other water inlet pipe. Compared with the related art, the post-adjustment of staff according to the specific water consumption of the user is not needed, and the operation is convenient.

Description

Economical intelligent water flow distribution management method and system

Technical Field

The application relates to the field of water flow distribution, in particular to a saving type intelligent water flow distribution management method and system.

Background

The intelligent water flow distribution management method and system is one water resource saving management method and system for reasonable water resource distribution.

At present, a water flow distribution system in the related art comprises two water inlet pipes, wherein the water inlet pipes are provided with two branch pipes, and the branch pipes are provided with regulating valves. When in use, the flow of the inlet water is changed by firstly adjusting the regulating valve according to the water consumption of a user.

In carrying out the present application, the inventors have found that at least the following problems exist in this technology: the water flow is regulated manually according to the water consumption of a user, and the operation is complicated, so that the improvement is needed.

Disclosure of Invention

In order to solve the problem of complicated operation of adjusting the water flow, the application provides a saving type intelligent water flow distribution management method and system.

In a first aspect, the present application provides a method and a system for saving intelligent water flow distribution management, which adopts the following technical schemes:

the economical intelligent water flow distribution management system comprises two water inlet pipes and two water reservoirs, wherein the water inlet pipes are in one-to-one correspondence with the water reservoirs, the two water inlet pipes are communicated with a direct connection pipe and a separate connection pipe, the direct connection pipe is connected with the water reservoirs corresponding to the water inlet pipes connected with the direct connection pipe, and the separate connection pipe is connected with the other water reservoir;

wherein, an adjusting component for changing the water flow in the direct connection pipe and the branch connection pipe is connected between the direct connection pipe on any water inlet pipe and the branch connection pipe on the other water inlet pipe, the rated liquid level is set in the reservoir according to the requirement, when the liquid level in any reservoir is lower than the rated liquid level, the adjusting component increases the water flow of the direct connection pipe and the split connection pipe connected with the reservoir, and when the liquid level in any reservoir is higher than the liquid level, the adjusting component decreases the water flow of the direct connection pipe and the split connection pipe connected with the reservoir.

Through adopting above-mentioned technical scheme, when the liquid level in any cistern is less than rated liquid level, the adjusting component will increase the water flow of the direct connection pipe and the branch connection pipe that the cistern is connected, and when the liquid level in any cistern is higher than the liquid level, the adjusting component will reduce the water flow of the direct connection pipe and the branch connection pipe that the cistern is connected, and whole adjustment process is automatically regulated, need not the staff and adjusts according to user's specific water consumption later stage, simple operation.

Optionally, the adjusting part comprises a floating ball, a rack and a gear, wherein the floating ball is positioned in the reservoir, a fixed screen plate used for limiting the floating ball to float along the vertical direction is arranged in the reservoir, a supporting rod is fixedly arranged on the inner wall of the fixed screen plate, the floating ball is supported on the supporting rod, a mounting rail is arranged on the inner wall of the direct connecting pipe, the rack is adaptively inserted and slides in the mounting rail, one end of the rack is positioned in the mounting rail, the other end of the rack is connected with the floating ball, a rotating column is rotatably connected on the inner wall of the direct connecting pipe, the gear is coaxially fixed with the rotating column, and the gear is meshed with the rack;

one end of the rotating column extends out of the direct connecting pipe, a driving gear is coaxially fixed at one end of the rotating column extending out of the direct connecting pipe, a flow plate is arranged in the direct connecting pipe, a rotating shaft is rotatably connected to the inner wall of the direct connecting pipe, one end of the rotating shaft is fixedly connected with the flow plate, the other end of the rotating shaft extends out of the direct connecting pipe, a driven gear is coaxially fixed at one end of the direct connecting pipe, the driving gear is meshed with the driven gear, a flow plate is also arranged inside the branch connecting pipe, a connecting rod is rotatably connected inside the branch connecting pipe, one end of the connecting rod is fixedly connected with the flow plate, the other end of the connecting rod extends out of the branch connecting pipe, a connecting gear is coaxially fixedly arranged at one end of the connecting rod extending out of the branch connecting pipe, and the connecting gear is meshed with the driven gear connected with the corresponding direct connecting pipe of the reservoir.

By adopting the technical scheme, when the water inlet pipe is filled with water and then stores water into the reservoirs, then according to the water consumption of users, if the water consumption of the two reservoirs is large, the floating ball moves downwards at the moment, the floating ball drives the rack to slide in the mounting rail in the process, the rack slides to drive the gear to rotate, the gear rotates to drive the driving gear to rotate through the rotating column, and the rotation of the driving gear drives the driven gear and the connecting gear to rotate in sequence, so that the flow plates in the direct connection pipe and the separation pipe are opened and water is supplied into the reservoirs; if the water consumption of one reservoir is high, the water consumption of the other reservoir is low, at this time, the floating ball in the reservoir with low water consumption is fast raised until the water inlet is closed, the floating ball in the process drives the rack, the gear, the driving gear, the driven gear and the connecting gear to rotate in sequence, so that the straight connecting pipe and the inner flow plate in the separating pipe connected with the reservoir with low water consumption seal the straight connecting pipe and the separating pipe connected with the same reservoir without water, at this time, the straight connecting pipe connected with the reservoir with high water consumption is used for filling all water into the reservoir, the separating pipe connected with the reservoir with low water consumption is used for filling all water into the reservoir until the water inlet is fast filled with the reservoir with high water consumption, and the floating ball in the process drives the rack, the gear, the driving gear, the driven gear and the connecting gear to rotate in sequence, so that the straight connecting pipe and the inner flow plate in the separating pipe connected with the reservoir with high water consumption seal the straight connecting pipe and the separating pipe connected with the same reservoir without water; the support bar prevents the flow plate from rotating repeatedly.

Optionally, the direct connection pipe lateral wall is provided with the supporting shoe, the supporting shoe roof has been seted up and has been placed the hole, place downthehole adaptation and insert and be equipped with the oil immersion sponge, the one end of oil immersion sponge with the driving gear looks butt, the other end with place and be connected with between the hole bottom of hole will the oil immersion sponge to driving gear department promotes first spring.

By adopting the technical scheme, the oil immersion sponge smears lubricating oil on the driving gear so as to reduce friction force among the driving gear, the driven gear and the connecting gear; through the elasticity of first spring, smear more lubricating oil in the oil-immersed sponge on the driving gear to further improved lubricated effect.

Optionally, place downthehole adaptation and insert and establish and slide and have hollow oil storage tank, the oil storage tank bottom with first spring is kept away from place the one end at hole bottom is fixed continuous, the top of oil storage tank is accepted the oil immersion sponge, the oil immersion hole has been seted up at the oil storage tank top, the sponge strip is worn to be equipped with by the oil immersion hole, the one end of sponge strip insert establish to in the oil storage tank, the other end with the oil immersion sponge links to each other, the tank filler hole has been seted up to the supporting shoe lateral wall, just the tank filler hole with the oil storage tank is linked together, the interference is inserted in the tank filler hole has the rubber buffer.

By adopting the technical scheme, the oiling hole is convenient for regularly oiling the oil storage tank, so that the lubricating effect is maintained; when the rubber plug is not used for adding oil, external dust is not easy to enter the oil storage tank from the oil filling hole.

Optionally, the water inlet pipe comprises a first pipe and a second pipe, a sleeve is communicated between the first pipe and the second pipe, and a filtering component is arranged on the inner wall of the sleeve;

the filter component comprises a filter screen cloth, a quartz sand layer, an activated carbon layer, a fluffy cotton layer and a receiving screen plate, wherein the filter screen cloth, the quartz sand layer, the activated carbon layer, the fluffy cotton layer and the receiving screen plate are sequentially in butt joint with each other in the direction from the first pipe to the second pipe.

Through adopting above-mentioned technical scheme, filter screen cloth, quartz sand layer, active carbon layer and fluffy cotton layer are convenient for purify the water layer to optimized quality of water.

Optionally, the filter screen cloth is provided with the lantern ring, the lantern ring with sleeve inner wall threaded connection, be located in the sleeve accept the otter board keep away from the fixed support ring board that is provided with in one side of fluffy cotton layer, support ring board with accept between the otter board connect will quartz sand layer the activated carbon layer fluffy cotton layer reaches accept the otter board to the second spring that sleeve pushed outward.

By adopting the technical scheme, when the filter screen cloth is screwed into the sleeve, the quartz sand layer, the activated carbon layer, the fluffy cotton layer and the receiving screen plate can be compressed in the sleeve through the deformation of the second spring; when the quartz sand layer, the activated carbon layer and the fluffy cotton layer need to be replaced, the filter screen cloth is screwed out of the sleeve, and at the moment, the quartz sand layer, the activated carbon layer and the fluffy cotton layer are automatically ejected out of the sleeve through the elasticity of the second spring, so that replacement is facilitated, and operation is convenient.

Optionally, the side walls of the reservoir are provided with yielding holes, the inner walls of the yielding holes are provided with sliding holes, sliding covers are inserted in the sliding holes in an adapting manner, and the sliding covers can axially slide along the sliding holes;

the floating ball penetrates through the sliding groove, one end of the rack, which extends out of the mounting rail, is inserted into and slides in the sliding groove, a plurality of limiting holes are formed in the side wall of the rack, a placement hole is formed in the inner wall of the sliding groove, a limiting rod is inserted into the placement hole in an adapting mode, the limiting rod is inserted into the limiting hole in an adapting mode, and a third spring which pushes the limiting rod into the limiting hole is connected between one end, away from the limiting hole, of the limiting rod and the bottom of the placement hole;

the floating ball is provided with a disassembly hole, the disassembly hole is communicated with the placement hole, one end of the limiting rod in the placement hole is fixedly connected with a disassembly rope, and the other end of the disassembly rope penetrates through the placement hole and the disassembly hole.

Through adopting above-mentioned technical scheme, open the sliding closure earlier and get into inside the cistern, then according to required rated liquid level, hold earlier and dismantle the rope and pull back the gag lever post in the mounting hole, then select required spacing hole to slide the rack to this spacing hole with the mounting hole coaxial line, loosen the hand at last, the gag lever post will be through the automatic control of inserting this spacing hole of the elasticity of third spring, thereby reach required rated liquid level, and the simple operation.

Optionally, a fourth spring for pushing the sliding cover outwards to the sliding hole is connected between one end of the sliding cover in the sliding hole and the bottom of the sliding hole;

the sliding cover is characterized in that a sealing groove is formed in the side wall of the sliding cover, a sealing strip is arranged on the inner wall of the yielding hole, and the sealing strip is inserted into the sealing groove in an interference mode.

By adopting the technical scheme, the fourth spring is convenient for the sliding cover not to easily slide back into the sliding hole when the sliding cover is closed in the closed state, so that the stability of the sliding cover is improved; when the sliding cover is closed, the sealing strip is inserted into the sealing groove in an interference mode, the sealing performance of the reservoir is improved, and dust is not easy to enter the reservoir.

Optionally, the fixed screen plate side wall is provided with a plurality of storage holes, the storage holes are rotationally connected with support columns, the support columns are fixedly connected with ladder plates, ratchet wheels are coaxially fixed on the support columns, pawls are rotationally connected to the inner walls of the storage holes, and the pawls are meshed with the ratchet wheels;

the storage Kong Dingbi is provided with a blocking hole, a blocking plate is inserted in the blocking hole in an adapting mode and slides in the blocking hole, a fifth spring which pushes the blocking plate outwards from the blocking hole is connected between one end of the blocking plate in the blocking hole and the bottom of the blocking hole, and when the blocking plate is stored in the storage hole, the blocking plate is abutted to the ladder plate.

Through adopting above-mentioned technical scheme, during the use, finely tune the pawl and upwards rotate first, make pawl and ratchet separation, then rotate out the ladder board from accomodating the hole until rotatory for the level, finally mesh ratchet and pawl again, make the ladder board can keep horizontal locking to the staff of being convenient for reachs fixed otter board top through the ladder board, and then be convenient for adjust the rack and lie in the degree of depth of spout; when the ladder is stored, the blocking plate can be compressed into the blocking hole through deformation of the fifth spring by hand, then the ladder plate is rotated into the storage hole, then the hand is loosened, the blocking plate can automatically extend out of the blocking hole through elastic force of the fifth spring, and the blocking plate is abutted with the ladder plate, so that the ladder plate can be stably stored in the storage hole.

In a second aspect, the present application provides a saving intelligent water flow distribution management method, which adopts the following technical scheme:

a saving type intelligent water flow distribution management method comprises the following steps:

s1, setting a rated liquid level in a reservoir and using the reservoir for domestic water supply;

s2, two water inlet pipes are communicated with the same water source, two water reservoirs are both filled to the rated liquid level, and the direct connection pipe and the split connection pipe are closed by the adjusting component;

s3, when the liquid level in any reservoir is lower than the rated liquid level, increasing the water flow in the direct connection pipe and the split connection pipe which are communicated with the reservoir through the adjusting component, and when the liquid level in the reservoir reaches the rated liquid level, closing the direct connection pipe and the split connection pipe by the adjusting component;

when the liquid level in the two reservoirs is lower than the rated liquid level and the liquid level of one reservoir is lower than the liquid level of the other reservoir, the water flow of the direct connection pipe and the separate connection pipe connected with the reservoir with lower liquid level is larger than that of the direct connection pipe and the separate connection pipe connected with the reservoir with higher liquid level through synchronous adjustment of the two adjusting components.

Through adopting above-mentioned technical scheme, can realize the distribution of rivers automatically, need not the manual regulation of later stage, and the simple operation.

In summary, the present application includes at least one of the following beneficial effects:

1. when the liquid level in any reservoir is lower than rated liquid level, the adjusting component can increase the water flow of the direct connecting pipe and the branch connecting pipe connected with the reservoir, when the liquid level in any reservoir is higher than the liquid level, the adjusting component can reduce the water flow of the direct connecting pipe and the branch connecting pipe connected with the reservoir, the whole adjusting process is automatic, no staff is required to adjust according to the later period of specific water consumption of users, and the operation is convenient.

2. The oil immersion sponge smears lubricating oil on the driving gear so as to reduce friction force among the driving gear, the driven gear and the connecting gear; through the elasticity of first spring, smear more lubricating oil in the oil-immersed sponge on the driving gear to further improved lubricated effect.

3. When the rack is used, fine adjustment is performed to enable the pawl to rotate upwards, so that the pawl is separated from the ratchet wheel, then the ladder plate rotates out of the storage hole until the rotation is horizontal, and finally the ratchet wheel is meshed with the pawl, so that the ladder plate can be locked horizontally, a worker can conveniently reach the position above the fixed screen plate through the ladder plate, and the depth of the rack positioned in the chute can be conveniently adjusted; when the ladder is stored, the blocking plate can be compressed into the blocking hole through deformation of the fifth spring by hand, then the ladder plate is rotated into the storage hole, then the hand is loosened, the blocking plate can automatically extend out of the blocking hole through elastic force of the fifth spring, and the blocking plate is abutted with the ladder plate, so that the ladder plate can be stably stored in the storage hole.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present application;

FIG. 2 is a schematic diagram of a filter assembly according to an embodiment of the present application;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is a schematic diagram of a structure for showing a connection relationship between a slide hole and a slide cover according to an embodiment of the present application;

FIG. 5 is a partial enlarged view at B in FIG. 4;

FIG. 6 is a schematic diagram of a structure for representing the connection relationship between a floating ball and a rack in an embodiment of the present application;

FIG. 7 is an enlarged view of a portion of FIG. 6 at C;

FIG. 8 is a partial enlarged view at D in FIG. 6;

FIG. 9 is a schematic diagram of a structure for representing a connection relationship between a limiting hole and a limiting rod in an embodiment of the present application;

FIG. 10 is a schematic diagram of a connection between a driving gear and a driven gear according to an embodiment of the present application;

FIG. 11 is an enlarged view of a portion of FIG. 10 at E;

FIG. 12 is an enlarged view of a portion of FIG. 10 at F;

FIG. 13 is a schematic view of a connection relationship between a ladder plate and a receiving hole according to an embodiment of the present application;

fig. 14 is a partial enlarged view at G in fig. 13.

In the figure: 1. a water inlet pipe; 11. a direct connection pipe; 12. a separating and connecting pipe; 3. an adjustment assembly; 5. a floating ball; 51. a chute; 52. a mounting hole; 53. a limit rod; 54. a third spring; 55. disassembling the hole; 56. disassembling the rope; 6. a rack; 61. a limiting hole; 7. a gear; 8. rotating the column; 81. a drive gear; 9. a rotation shaft; 91. a driven gear; 92. a flow plate; 101. a connecting rod; 102. a connecting gear; 103. a support block; 104. placing the hole; 105. an oil storage tank; 106. soaking the oil sponge; 107. a first spring; 108. an oil immersion hole; 109. a sponge strip; 201. a fuel filler hole; 202. a rubber stopper; 203. a first tube; 204. a second pipe; 205. a sleeve; 206. a filter assembly; 207. a filter screen cloth; 208. a collar; 209. a quartz sand layer; 301. an activated carbon layer; 302. a fluffy cotton layer; 303. a receiving screen plate; 304. a second spring; 305. a support ring plate; 306. a reservoir; 308. a relief hole; 309. a slide hole; 401. a sliding cover; 402. sealing grooves; 403. a sealing strip; 404. a fourth spring; 405. fixing the screen plate; 406. a support rod; 407. a receiving hole; 408. a support column; 409. a ladder plate; 501. a ratchet wheel; 502. a pawl; 503. blocking the hole; 504. a blocking plate; 505. a fifth spring; 506. and (3) mounting a rail.

Detailed Description

The application is described in further detail below with reference to fig. 1-14.

The embodiment of the application discloses an economical intelligent water flow distribution management system. Referring to fig. 1, an intelligent water-saving water distribution management system includes two water inlet pipes 1 and two water reservoirs 306, wherein the water inlet pipes 1 and the water reservoirs 306 are in one-to-one correspondence, the water inlet pipes 1 include a first pipe 203 and a second pipe 204, and the first pipe 203 and the second pipe 204 are fixed through flanges. The two water inlet pipes 1 are respectively provided with a direct connecting pipe 11 and a branch connecting pipe 12 in a communicating way, the direct connecting pipe 11 is connected with a reservoir 306 corresponding to the water inlet pipe 1 connected with the direct connecting pipe, and the branch connecting pipe 12 is connected with another reservoir 306.

Referring to fig. 2 and 3, a sleeve 205 is screwed to the inner wall of the joint between the first tube 203 and the second tube 204, and a filter assembly 206 is disposed in the sleeve 205. The filter assembly 206 comprises a filter screen cloth 207, a quartz sand layer 209, an activated carbon layer 301, a fluffy cotton layer 302 and a receiving screen 303, wherein the filter screen cloth 207, the quartz sand layer 209, the activated carbon layer 301, the fluffy cotton layer 302 and the receiving screen 303 are sequentially arranged along the direction from the first pipe 203 to the second pipe 204, so that the water layer is conveniently purified, and the water quality is optimized. The peripheral wall of the filter screen cloth 207 is glued with a collar 208, and the filter screen cloth 207 is in threaded connection with the inner wall of the sleeve 205 through the collar 208, so that the filter screen cloth 207 can be detached, thereby being convenient for regular cleaning or replacement. The quartz sand layer 209, the activated carbon layer 301, the fluffy cotton layer 302 and the receiving screen 303 can slide in the sleeve 205.

Referring to fig. 3, in addition, a supporting ring plate 305 is welded and fixed on one side of the supporting plate, which is far away from the fluffy cotton layer 302, in the sleeve 205, and a second spring 304 for pushing the supporting ring plate 303 to one side, which is far away from the supporting ring plate 305, is welded between the supporting ring plate 305 and the supporting net plate 303, and when the filter screen cloth 207 is screwed into the sleeve 205, the quartz sand layer 209, the activated carbon layer 301, the fluffy cotton layer 302 and the supporting net plate 303 can be compressed in the sleeve 205 through deformation of the second spring 304; when the quartz sand layer 209, the activated carbon layer 301 and the fluffy cotton layer 302 need to be replaced, the filter screen cloth 207 is screwed out of the sleeve 205, and at the moment, the quartz sand layer 209, the activated carbon layer 301 and the fluffy cotton layer 302 automatically pop out of the sleeve 205 through the elasticity of the second spring 304, so that replacement is facilitated, and operation is convenient and fast.

Referring to fig. 4 and 5, the side walls of the two reservoirs 306 are provided with through holes 308, the inner wall of one side of the through hole 308 along the length direction is provided with sliding holes 309, and sliding covers 401 are inserted and slid in the sliding holes 309. A fourth spring 404 for pushing the sliding cover 401 to the outside of the sliding hole 309 is welded between one end of the sliding cover 401 in the sliding hole 309 and the hole bottom of the sliding hole 309, so that the sliding cover 401 is not easy to slide back into the sliding hole 309 when being closed, and the closing stability of the sliding cover 401 is improved. The side walls of the sliding cover 401 extending out of the sliding hole 309 are provided with sealing grooves 402, sealing strips 403 are glued to the inner walls of the yielding holes 308, and when the sliding cover 401 is closed, the sealing strips 403 are inserted into the sealing grooves 402 in an interference manner, so that the tightness of the reservoir 306 is improved, and dust in the reservoir 306 is not easy to enter.

Referring to fig. 6, a regulating component 3 for changing the water flow in the direct connection pipe 11 and the split connection pipe 12 is connected between the two direct connection pipes 11 and the split connection pipe 12 on the other water inlet pipe 1. The water inlets of the two reservoirs 306 are welded with fixed mesh plates 405, and the fixed mesh plates 405 are cylindrical.

Referring to fig. 7 and 8, the adjusting component 3 includes floating balls 5, racks 6 and gears 7, the two floating balls 5 are adapted to be positioned in the two fixed net plates 405, and float up and down in the fixed net plates 405 along the vertical direction, and when the floating balls 5 float to the top, the water inlet can be completely closed. The mounting rail 506 is arranged on the inner wall of the direct connection pipe 11, the rack 6 is inserted and slides in the mounting rail 506 in an adapting mode, the floating ball 5 is provided with the sliding groove 51 in a penetrating mode in the vertical direction, one end of the rack 6 slides in the mounting rail 506, and the other end of the rack 6 slides in the sliding groove 51.

Referring to fig. 9, a plurality of limiting holes 61 are formed in the side wall of the rack 6, which is adjacent to the toothed slot of the rack 6, a mounting hole 52 is formed in the side wall of the chute 51 opposite to the limiting holes 61, a limiting rod 53 is inserted in the mounting hole 52 in an adapting manner, one end of the limiting rod 53 extending out of the mounting hole 52 is inserted in the limiting hole 61 in an adapting manner, a third spring 54 for pushing the limiting rod 53 into the limiting hole 61 is welded between one end of the limiting rod 53 away from the limiting hole 61 and the bottom of the mounting hole 52, and the limiting rod 53 is not easy to slide back into the mounting hole 52 from the limiting hole 61 by the elastic force of the third spring 54. The floating ball 5 is provided with the dismounting hole 55, the dismounting hole 55 is communicated with the mounting hole 52, one end of the limiting rod 53, which is positioned in the mounting hole 52, is glued with the dismounting rope 56, the other end of the dismounting rope 56 is penetrated through the mounting hole 52 and the dismounting hole 55, according to the required rated liquid level, the dismounting rope 56 is held firstly to pull the limiting rod 53 back into the mounting hole 52, then the required limiting hole 61 is selected, the rack 6 is slid to the coaxial line of the limiting hole 61 and the mounting hole 52, finally, the hand is released, and the limiting rod 53 is automatically inserted into the limiting hole 61 through the elastic force of the third spring 54, so that the control of the required rated liquid level is achieved, and the operation is convenient.

Referring to fig. 10 and 11, the inner walls of the two straight connecting pipes 11 are both rotatably connected with a rotating column 8, the gear 7 and the rotating column 8 are coaxially welded and fixed, and the gear 7 is meshed with the rack 6. One end of the rotating column 8 extends out of the straight connecting tube 11, one end of the rotating column 8 extending out of the straight connecting tube 11 is fixedly welded with the driving gear 81 in a coaxial line mode, a flow plate 92 consistent with the inner diameter of the straight connecting tube 11 is arranged inside the straight connecting tube 11, the flow plate 92 is located above the gear 7, the inner walls of the two straight connecting tubes 11 are rotationally connected with the rotating shafts 9, one end portion of the rotating shafts 9 is fixedly welded with the outer ring side wall of the flow plate 92 in a welded mode, the other end of the rotating shafts 9 extends out of the straight connecting tube 11, one end of the rotating shafts extending out of the straight connecting tube 11 is fixedly welded with the driven gear 91 in a coaxial line mode, and the driven gear 91 is meshed with the driving gear 81. The inside of the two branch connecting pipes 12 is also provided with a flow plate 92 which is consistent with the inner diameter of the branch connecting pipes 12, the inner walls of the two branch connecting pipes 12 are also rotationally connected with a connecting rod 101, one end part of the connecting rod 101 is fixedly welded with the outer ring side wall of the flow plate 92, one end of the connecting rod 101 extending out of the branch connecting pipe 12 is fixedly welded with a connecting gear 102 in a coaxial line manner, the connecting gear 102 connected with the branch connecting pipe 12 is meshed with a driven gear 91 connected with a direct connecting pipe 11 of a corresponding reservoir 306, the diameters of the driving gear 81, the driven gear 91 and the connecting gear 102 are consistent, when the water inlet pipe 1 is filled with water into the reservoir 306, then according to the water consumption of a user, if the water consumption of the two reservoirs 306 is large, the floating ball 5 moves downwards, in the process, the floating ball 5 drives a rack 6 to slide in a mounting rail 506, the rack 6 slides to drive the gear 7 to rotate, the driving gear 81 is driven by a rotating column 8, and the driving gear 81 is sequentially driven by the rotating of the driving gear 81, the driving gear 91 and the connecting gear 102, so that the direct pipe 11 and the flow plate 306 in the branch connecting pipe 12 are opened; if the water consumption of one reservoir 306 is high, the water consumption of the other reservoir 306 is low, at this time, the floating ball 5 in the reservoir 306 with low water consumption rises rapidly until the water inlet is closed, the floating ball 5 of the reservoir 306 with high water consumption drives the rotation of the rack 6, the gear 7, the driving gear 81, the driven gear 91 and the connecting gear 102 in turn, so that the flow plate 92 in the direct connection pipe 11 and the branch connection pipe 12 connected with the reservoir 306 with low water consumption seal the direct connection pipe 11 and the branch connection pipe 12 connected with the same reservoir 306 without water, at this time, the direct connection pipe 11 connected with the reservoir 306 with high water consumption charges all water into the reservoir 306, and the branch connection pipe 12 connected with the reservoir 306 with low water consumption charges all water into the reservoir 306 until the floating ball 5 of the reservoir 306 with high water consumption seals the water inlet after the reservoir 306 with high water consumption is filled rapidly, and the upper floating ball 5 of the reservoir 306 with high water consumption drives the rack 6, the gear 7, the driving gear 81, the driven gear 91 and the connecting gear 102 in turn, so that the direct connection pipe 11 and the branch connection pipe 12 connected with high water consumption reservoir 306 seal the direct connection pipe 11 and the branch connection pipe 12 without water consumption.

In addition, the inner wall of the fixed screen 405 is welded with a supporting rod 406, and the supporting rod 406 is used for receiving the floating ball 5, so that the floating ball 5 cannot continuously sink downwards, and the flow plate 92 cannot repeatedly rotate.

Referring to fig. 10 and 12, the outer side walls of the two direct connection pipes 11 are welded with a supporting block 103, the supporting block 103 is positioned below the driving gear 81, a placement hole 104 is formed in the top of the supporting block 103, an oil storage tank 105 is inserted in the placement hole 104 in an adapting mode and slides, an oil immersion sponge 106 is received in the top of the oil storage tank 105, one end, far away from the oil storage tank 105, of the oil immersion sponge 106 is abutted to the driving gear 81, an oil immersion hole 108 is formed in the top wall of the oil storage tank 105, a sponge strip 109 penetrates through the oil immersion hole 108, one end of the sponge strip 109 is inserted into the oil storage tank 105, the other end of the sponge strip 109 is integrally formed with the oil immersion sponge 106, a first spring 107 pushing the oil immersion sponge 106 to the driving gear 81 is welded between the bottom of the oil storage tank 105 and the bottom of the placement hole 104, lubricating oil is transferred to the oil immersion sponge 106 through the sponge strip 109, and then lubricating oil is smeared on the driving gear 81 through the oil immersion sponge 106, so that friction force among the driving gear 81, the driven gear 91 and the connecting gear 102 is reduced; more lubricating oil in the oil-impregnated sponge 106 is smeared on the driving gear 81 by the elastic force of the first spring 107, thereby further improving the lubricating effect.

In addition, the oil filling hole 201 is formed in the top wall of the supporting block 103, and the oil filling hole 201 is communicated with the oil storage tank 105, so that oil can be filled in the oil storage tank 105 at regular intervals, and the lubricating effect is maintained. The rubber plug 202 is inserted in the oil filling hole 201 in an interference manner, so that external dust is not easy to enter the oil storage tank 105 from the oil filling hole 201 when oil is not filled.

Referring to fig. 13 and 14, a plurality of receiving holes 407 are formed in the side wall of the fixed mesh plate 405 at the non-grid position, in the embodiment of the application, two receiving holes 407 are formed in the side wall of the fixed mesh plate 405, the inner side wall of each receiving hole 407 is rotatably connected with a supporting column 408, a ladder plate 409 is fixedly welded on each supporting column 408, a ratchet wheel 501 is coaxially welded on each supporting column 408, the bottom of each receiving hole 407 is rotatably connected with a pawl 502, each pawl 502 is meshed with each ratchet wheel 501, when in use, the pawls 502 are firstly finely adjusted to rotate upwards, the pawls 502 are separated from the ratchet wheels 501, then the ladder plate 409 is rotated out from the receiving holes 407 until the pawls are rotated to be horizontal, and finally, the ratchet wheels 501 are meshed with the pawls 502, so that the ladder plate 409 can be kept horizontally locked, thereby being convenient for workers to reach the upper side of the fixed mesh plate 405 through the ladder plate 409, and further being convenient for adjusting the depth of the racks 6 located in the sliding grooves 51.

In addition, the top wall in the accommodating hole 407 is provided with a blocking hole 503, a blocking plate 504 is inserted and slides in the blocking hole 503, a fifth spring 505 for pushing the blocking plate 504 out of the blocking hole 503 is welded between one end in the blocking hole 503 and the bottom of the blocking hole 503, when the accommodating hole is accommodated, the blocking plate 504 can be compressed into the blocking hole 503 by the deformation of the fifth spring 505 by hand, then the ladder plate 409 is rotated into the accommodating hole 407, then the hand is released, the blocking plate 504 can automatically extend out of the blocking hole 503 by the elastic force of the fifth spring 505, and the blocking plate 504 is abutted against the ladder plate 409, so that the ladder plate 409 can be stably accommodated in the accommodating hole 407.

The implementation principle of the economical intelligent water flow distribution management system provided by the embodiment of the application is as follows: when the water inlet pipe 1 is filled with water and then stores water into the reservoirs 306, if the water consumption of the two reservoirs 306 is large, the floating ball 5 moves downwards at the moment, in the process, the floating ball 5 drives the rack 6 to slide in the mounting rail 506, the sliding of the rack 6 drives the gear 7 to rotate, the gear 7 rotates to drive the driving gear 81 to rotate through the rotating column 8, and the rotation of the driving gear 81 drives the driven gear 91 and the connecting gear 102 to rotate in sequence, so that the flow plates 92 in the direct connection pipe 11 and the branch connection pipe 12 are opened and water is supplied into the reservoirs 306; if the water consumption of one reservoir 306 is high, the water consumption of the other reservoir 306 is low, at this time, the floating ball 5 in the reservoir 306 with low water consumption rises rapidly until the water inlet is closed, the floating ball 5 of the reservoir 306 with high water consumption drives the rotation of the rack 6, the gear 7, the driving gear 81, the driven gear 91 and the connecting gear 102 in turn, so that the flow plate 92 in the direct connection pipe 11 and the branch connection pipe 12 connected with the reservoir 306 with low water consumption seal the direct connection pipe 11 and the branch connection pipe 12 connected with the same reservoir 306 without water, at this time, the direct connection pipe 11 connected with the reservoir 306 with high water consumption charges all water into the reservoir 306, and the branch connection pipe 12 connected with the reservoir 306 with low water consumption charges all water into the reservoir 306 until the floating ball 5 of the reservoir 306 with high water consumption seals the water inlet after the reservoir 306 with high water consumption is filled rapidly, and the upper floating ball 5 of the reservoir 306 with high water consumption drives the rack 6, the gear 7, the driving gear 81, the driven gear 91 and the connecting gear 102 in turn, so that the direct connection pipe 11 and the branch connection pipe 12 connected with high water consumption reservoir 306 seal the direct connection pipe 11 and the branch connection pipe 12 without water consumption.

The embodiment of the application also discloses a saving type intelligent water flow distribution management method.

The economical intelligent water flow distribution management method comprises the following steps:

s1, setting a rated liquid level in a reservoir 306 and using the reservoir 306 for domestic water supply;

s2, connecting the two water inlet pipes 1 with the same water source, filling the two water reservoirs 306 to the rated liquid level, and closing the direct connection pipe 11 and the split connection pipe 12 by the adjusting component 3;

s3, when the liquid level in any reservoir 306 is lower than the rated liquid level, the water flow in the direct connection pipe 11 and the split connection pipe 12 which are communicated with the reservoir 306 is increased through the adjusting component 3, and when the liquid level in the reservoir 306 reaches the rated liquid level, the adjusting component 3 closes the direct connection pipe 11 and the split connection pipe 12;

when the liquid level in the two reservoirs 306 is lower than the rated liquid level and the liquid level of one reservoir 306 is lower than the liquid level of the other reservoir 306, the two adjusting assemblies 3 are synchronously adjusted so that the water flow of the direct connection pipe 11 and the split connection pipe 12 connected with the reservoir 306 with lower liquid level is larger than that of the direct connection pipe 11 and the split connection pipe 12 connected with the reservoir 306 with higher liquid level.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (9)

1. The utility model provides a saving type intelligent water flow distribution management system, includes two inlet tube (1) and two cistern (306), inlet tube (1) with cistern (306) one-to-one, two inlet tube (1) all communicate and are provided with direct connecting pipe (11) and branch connecting pipe (12), direct connecting pipe (11) with rather than linking to each other inlet tube (1) corresponding cistern (306) link to each other, branch connecting pipe (12) with another cistern (306);

the method is characterized in that: wherein, an adjusting component (3) for changing the water flow in the direct connection pipe (11) and the separation pipe (12) is connected between the direct connection pipe (11) on any water inlet pipe (1) and the separation pipe (12) on the other water inlet pipe (1);

setting rated liquid level in the reservoir (306) according to the requirement, when the liquid level in any reservoir (306) is lower than the rated liquid level, the adjusting component (3) increases the water flow of the direct connection pipe (11) and the split connection pipe (12) connected with the reservoir (306) with the liquid level lower than the rated liquid level, and when the liquid level in any reservoir (306) is higher than the liquid level, the adjusting component (3) decreases the water flow of the direct connection pipe (11) and the split connection pipe (12) connected with the reservoir (306) with the liquid level higher than the rated liquid level;

the adjusting component (3) comprises a floating ball (5), a rack (6) and a gear (7), wherein the floating ball (5) is positioned in the water reservoir (306), a fixed screen plate (405) used for limiting the floating ball (5) to float along the vertical direction is arranged in the water reservoir (306), a supporting rod (406) is fixedly arranged on the inner wall of the fixed screen plate (405), the floating ball (5) is supported on the supporting rod (406), a mounting rail (506) is arranged on the inner wall of the direct connecting pipe (11), the rack (6) is adaptively inserted and slides in the mounting rail (506), one end of the rack (6) is positioned in the mounting rail (506), the other end of the rack is connected with the floating ball (5), the inner wall of the direct connecting pipe (11) is rotationally connected with a rotating column (8), the gear (7) is coaxially fixed with the rotating column (8), and the gear (7) is meshed with the rack (6).

The utility model discloses a water heater, including straight connecting tube (11), including connecting rod (101), connecting rod (101) and connecting rod (12), rotation post (8)'s one end stretches out straight connecting tube (11), just rotation post (8) stretch out straight connecting tube (8)'s one end stretch out straight connecting tube (11), just rotation post (8) stretch out straight connecting tube (11)'s one end coaxial line fixedly provided with driven gear (91), driving gear (81) with driven gear (91) are meshed, branch connecting tube (12) inside also is provided with flow plate (92), branch connecting tube (12) inside rotation is connected with connecting rod (101), the one end of connecting rod (101) with flow plate (92) fixedly link to each other, the other end stretches out outside branch connecting tube (12), connecting rod (101) stretch out straight connecting tube (12) one end coaxial line fixedly provided with driven gear (91) meshes with driven gear (102), branch connecting tube (12) is connected with straight connecting tube (102).

2. An intelligent water conservation management system as claimed in claim 1 wherein: the oil immersion device is characterized in that a supporting block (103) is arranged on the outer side wall of the direct connection pipe (11), a placement hole (104) is formed in the top wall of the supporting block (103), an oil immersion sponge (106) is inserted in the placement hole (104) in an adaptive mode, one end of the oil immersion sponge (106) is abutted to the driving gear (81), and a first spring (107) pushing the oil immersion sponge (106) to the driving gear (81) is connected between the other end of the oil immersion sponge and the bottom of the placement hole (104).

3. An intelligent water conservation management system as claimed in claim 2 wherein: the oil storage device is characterized in that a hollow oil storage tank (105) is inserted in the placement hole (104) in a matched manner and slides, the bottom of the oil storage tank (105) is away from the first spring (107) and fixedly connected with one end of the bottom of the placement hole (104), the top of the oil storage tank (105) is connected with an oil immersion sponge (106), an oil immersion hole (108) is formed in the top of the oil storage tank (105), a sponge strip (109) is arranged in the oil immersion hole (108) in a penetrating manner, one end of the sponge strip (109) is inserted into the oil storage tank (105), the other end of the sponge strip is connected with the oil immersion sponge (106), an oil filling hole (201) is formed in the outer side wall of the supporting block (103), the oil filling hole (201) is communicated with the oil storage tank (105), and a rubber plug (202) is inserted in the oil filling hole (201) in an interference manner.

4. An intelligent water conservation management system as claimed in claim 1 wherein: the water inlet pipe (1) comprises a first pipe (203) and a second pipe (204), a sleeve (205) is communicated between the first pipe (203) and the second pipe (204), and a filtering component (206) is arranged on the inner wall of the sleeve (205);

the filter assembly (206) comprises a filter screen cloth (207), a quartz sand layer (209), an activated carbon layer (301), a fluffy cotton layer (302) and a receiving screen plate (303), wherein the filter screen cloth (207) is sequentially abutted to the direction from the first pipe (203) to the second pipe (204) through the quartz sand layer (209) the activated carbon layer (301) and the fluffy cotton layer (302) and the receiving screen plate (303).

5. The intelligent water conservation management system of claim 4, wherein: filter screen cloth (207) is provided with lantern ring (208), lantern ring (208) with sleeve (205) inner wall threaded connection, be located in sleeve (205) accept otter board (303) keep away from one side of fluffy cotton layer (302) is fixed to be provided with support ring board (305), support ring board (305) with accept to connect between otter board (303) will quartz sand layer (209) active carbon layer (301) fluffy cotton layer (302) reaches accept second spring (304) that otter board (303) promoted outward sleeve (205).

6. An intelligent water conservation management system as claimed in claim 1 wherein: a yielding hole (308) is formed in the side wall of the reservoir (306), a sliding hole (309) is formed in the inner wall of the yielding hole (308), a sliding cover (401) is inserted in the sliding hole (309) in an adapting mode, and the sliding cover (401) can axially slide along the sliding hole (309);

the floating ball (5) is provided with a sliding groove (51) in a penetrating mode, one end, extending out of the mounting rail (506), of the rack (6) is inserted into the sliding groove (51) in a sliding mode, a plurality of limiting holes (61) are formed in the side wall of the rack (6), a placing hole (52) is formed in the inner wall of the sliding groove (51), a limiting rod (53) is inserted into the placing hole (52) in an adapting mode, the limiting rod (53) is inserted into the limiting hole (61) in an adapting mode, and a third spring (54) pushing the limiting rod (53) into the limiting hole (61) is connected between one end, away from the limiting hole (61), of the limiting rod (53) and the bottom of the placing hole (52);

the floating ball (5) is provided with a disassembly hole (55), the disassembly hole (55) is communicated with the placement hole (52), one end of the limiting rod (53) in the placement hole (52) is fixedly connected with a disassembly rope (56), and the other end of the disassembly rope (56) penetrates through the placement hole (52) and the disassembly hole (55).

7. The intelligent water conservation management system of claim 6, wherein: a fourth spring (404) for pushing the sliding cover (401) to the outside of the sliding hole (309) is connected between one end of the sliding cover (401) in the sliding hole (309) and the hole bottom of the sliding hole (309);

the side wall of the sliding cover (401) is provided with a sealing groove (402), the inner wall of the yielding hole (308) is provided with a sealing strip (403), and the sealing strip (403) is inserted into the sealing groove (402) in an interference mode.

8. The intelligent water conservation management system of claim 6, wherein: a plurality of storage holes (407) are formed in the side wall of the fixed screen plate (405), support columns (408) are connected in the storage holes (407) in a rotating mode, ladder plates (409) are fixedly connected to the support columns (408), ratchet wheels (501) are coaxially fixed to the support columns (408), pawls (502) are connected to the inner walls of the storage holes (407) in a rotating mode, and the pawls (502) are meshed with the ratchet wheels (501);

the top wall of the storage hole (407) is provided with a blocking hole (503), a blocking plate (504) is inserted in the blocking hole (503) in a matched mode and slides, one end of the blocking plate (504) located in the blocking hole (503) is connected with a fifth spring (505) pushing the blocking plate (504) to the outside of the blocking hole (503) between the hole bottom of the blocking hole (503), and when the blocking plate (504) is stored in the storage hole (407), the blocking plate (504) is abutted to the ladder plate (409).

9. A method of management based on the intelligent water conservation management system of any one of claims 1-8, comprising the steps of:

s1, setting a rated liquid level in a reservoir (306) and using the reservoir (306) for domestic water supply;

s2, two water inlet pipes (1) are communicated with the same water source, two water reservoirs (306) are filled to rated liquid level, and the direct connection pipe (11) and the split connection pipe (12) are closed by the adjusting component (3) afterwards;

s3, when the liquid level in any reservoir (306) is lower than the rated liquid level, the water flow in the direct connection pipe (11) and the split connection pipe (12) which are communicated with the reservoir (306) is increased through the adjusting component (3), and when the liquid level in the reservoir (306) reaches the rated liquid level, the adjusting component (3) closes the direct connection pipe (11) and the split connection pipe (12);

when the liquid level in the two reservoirs (306) is lower than the rated liquid level and the liquid level of one reservoir (306) is lower than the liquid level of the other reservoir (306), the water flow of the direct connection pipe (11) and the separation pipe (12) connected with the reservoir (306) with lower liquid level is larger than the water flow of the direct connection pipe (11) and the separation pipe (12) connected with the reservoir (306) with higher liquid level through synchronous adjustment of the two adjusting components (3).